Fluorinated ether

ABSTRACT

The present invention relates to 1,1,1-trifluoro-2difluoromethoxy propane of the formula

Elite files alenl 1 1 [111. 3,869,519 Terrell 1 1 Mar. 4, 1975 1 1 FLUORINATED ETHER 3.352.928 11/1967 Gilbert et a1. 260/614 F x 3.476.860 11/1969 Croix et a1 260/614 F X 1751 R055 0 Terrell Plamfield- 3.594.484 7/1971 Gilbert et a1. 260/614 F [73] Assignee: Airco, Inc., Montvale NJ. OTHER PUBLICATIONS [22 Filed: Mar. 5, 1970 Mitsch et 211.. J. Heterocycle Chem. 2, 1965, p.

17308 Hine et 211., lacs, 80. 1958, p. 3002-3007.

Related U.S. Application Data [63] Continuation of Ser. No. 725.164. April 29. 1968. Mars abandoned. Attorney, Agent, or Fir/11R0ger M. Rathbun;

Edmund W. Bopp; H. Hume Mathews 152] 115. C1. 260/614 F, 106/311, 134/40.

252/171. 252/364, 424/342 [57] ABSTRACT 1 1 3 CL C079 43/12 The present invention relates to 1,1,l-trifluoro-2- Fleld of Search 1 P difluoromethoxy propane of the formula 156] References Cited CHF'ZOCMCHQCF" L-MTED STATES PATENTS This compound is useful as an anesthene and as a solv vent and dispersant of fluorinated materials.

1992.276 1/1961 \Ncmmuycr 260/614 F 363464411 10/1967 Gilbert 01 111. 260/614 F X 1 Claim, N0 Drawings FLUORINATED ETHER This is a continuation of application Ser. No. 725.164. filed Apr. 29, 1968 and now abandoned.

DESCRIPTION OF THE INVENTION This invention relates to novel anesthetic compositions containing l,1,1-trifluoro-2-difluoromethoxy propane. the preparation ofthe ether and its use in producing anesthesia in anesthetic susceptible air breathing mammals.

The compound 1,1,1-trifluoro-2-difluoromethoxy propane has the following formula:

It is normally a clear, colorless liquid with a not unpleasant odor. lt has the following physical properties: b.p. 48C at 760 mm., vapor pressure 330 mm. at 30C; specific gravity 1.4; and a molecular weight of 164. The compound is soda lime stable and is a potent anesthetic for inhalation anesthetic susceptible mammals. The compound is also easily miscible with other organic liquids including fats and oils and has useful solvent properties. for example, as a solvent for fluorinated olefins and other fluorinated materials such as fluoro waxes. It may be used to prepare pastes and dispersions of such materials useful for coatings and the like and may be used as a degreasing agent.

The compound 1,1,1-trifluoro-Z-difluoromethoxy propane is preferably prepared through the following series of reactions involving the stepwise chlorination and fluorination of l.Ll-trifluoro-Z-methoxy propane:

The compound 1.1,l-trifluoro-2-methoxy propane is a well known material which can be prepared by reacting 1.1.l-trifluoropropanol-Z with dimethyl sulfate in the presence of dissolved potassium hydroxide. The reaction is exothermic and is preferably carried out at temperatures below 30C. On completion of the reaction the desired 1.1.l-trifluoro-2-methoxy propane can be separated from the reaction mass and purified by fractional distillation.

The l.l,l-trifluoro-2-methoxy propane precursor is then chlorinated to form CHCI OCH(CH )CF The chlorination of CH OCH(CH )CF to form LHCl- O(H(CH3)CF should be carried out in either a fully or partially transparent vessel so that photo energy can be supplied to the reaction. Suitable sources of photo energy are incandescent. ultraviolet and fluorescent lamps and even strong sunlight. In view of the ready availability, low cost and ease of handling of incandescent lamps they are preferred for use as the illumination source.

The chlorination is carried out by bubbling gaseous chlorine into the liquid CH OCH(CH )CF while it is strongly illuminated. The chlorine is added at the same rate at which it reacts which can be determined by checking for chlorine vapor in the effluent from the chlorinator. The reaction is exothermic so cooling water should be supplied to the chlorination apparatus to control the reaction. The chlorination can be carried out at any temperature from C up to the boiling point of the chlorination mixture. Best results are usually found at 25-35C where the reaction rate is fast enough and the formation of byproducts does not present a serious problem.

The effluent from the chlorination apparatus should be passed through a water scrubber to dissolve the HCl which is formed. The chlorination should be continued until approximately 2.75 moles of HCl per mole of starting ether are detected by titration of the dissolved HCl with a standard base. The extent of the chlorination can be controlled by the amount of chlorine bubbled through the ether and determined by the amount of effluent HCl. If too little HCl is evolved it indicates that the chlorination product is the monochloro product. If too much HCl is determined it indicates that polychloro products have been formed or that the ether has decomposed into undesirable chlorinated reaction products.

The lower chlorination product can be separated from the reaction mass by fractional distillation followed by further chlorination in order to raise the yield of the desired product.

Following the chlorination the reaction mass can be separated by fractional distillation or by vapor phase chromatography. lf distillation is employed it is recommended that the pressure be reduced in view of the high molecular weight of the product CHCl OCH(CH )CF Excessive heating should obviously be avoided in view ofthe possibility of decomposing the desired product.

The thus prepared CHCI OCH(CH;,)CF should then be transferred to a reaction vessel that will not be attacked during the fluorination reaction. A stainless steel, copper, nickel, or platinum vessel would be quite suitable. A catalyst such as SbCl SnCl or SbF should be added to the chlorinated starting material before beginning the fluorination. The fluorination reaction can be carried out by bubbling gaseous HF through the reaction mixture or by adding solid SbF to the mixture.

The fluorination reaction is preferably carried out at 0C. Higher or lower temperatures can be employed, however, it has been found that higher temperatures produce undesirable reaction products while lower temperatures cause a slow rate of reaction.

The effluent from the fluorination apparatus should be passed through a water scrubber to collect the HCl which is formed during the reaction. The amount of HCl formed is equivalent to the number of chlorine atoms exchanged for fluorine. Too little HCl evolved indicates incomplete exchange. Too much HCl indicates either over fluorination or decomposition. The fluorination should be continued until approximately two moles of HCl are collected for each mole of CHCI OCH(CH )CF;, indicating that two chlorine atoms have been exchanged. The preferred site for the fluorination is on the chlorine substituted methyl group resulting in the formation of CHF OCH(CH )CF The desired reaction product can be readily separated from the reaction mixture by fractional distillation.

EXAMPLE 1 Synthesis of CH OCH(CH )CF Approximately 164 g. (1.3 moles) of (CH SO was purified by washing with cold water and cold saturated NaHCO solution until neutral. The dimethyl sulfate was then added slowly to a solution of 1 14 g. (1 mole) of CF -,(CH )CHOH and g. (1.25 mole) of KOH in cc. of water. The reaction was exothermic so it was necessary to cool the flask to keep the reaction mass below the boiling point. The product CH OCH(CH )CF 96 g.. b.p. 485C. was distilled directly from the reaction mixture EXAMPLE 2 P of CHCl OCH(CH- )CF Approximately 163 g. of CH OCH(CH )CF prepared as illustrated in Example 1 were added to a water jacketed chlorinator fitted with a thermometer, a Drylce" cold finger type condenser and a fritted glass gas dispersion tube. The reaction was carried out at 30C with gaseous chlorine being bubbled through the solution which was exposed to a source ofillumination. The effluent HCl was collected in a scrubber and aliquots were titrated with a standard base. The reaction was continued until 2.75 moles of HCI per mole of ether was titrated. Following the chlorination 254 g. of material were recovered.

Fractional distillation of this mixture gave 60 g. of CHCl OCH(CH )CF b.p. 113C, N 1.3785.

Calculated for C H Cl F O: C, 24.4; H, 2.54;

Found: C, 24.67; H, 2.55.

EXAMPLE 3 Preparation of CHF OCH(CH )CF A 1 liter 3 necked stainless steel flask was fitted with a copper "Dry-Ice" cold finger condenser, a stainless steel stirring shaft and gland and a copper gas inlet tube. To the flask there was then added 55 g. of CHCl OCH(CH )CF as prepared in Example 2, and 2.5 g. of SbCl HF gas was then slowly bubbled through the stirred mixture which was maintained at C. The reaction was run until 0.4 moles of HCl was collected, as indicated by the titration of the effluent HCI which was dissolved in water. Following the fluorination. 41 g. of material were recovered. Fractional distillation using a 30 X 0.5 cm. column packed with glass helices gave the pure 22 g. of CHF- OCH(CH )CF b.p 48C at 760 mm.

Calculated for C H F O: C, 29.35; H, 3.06; F, 58.0;

Found: C, 29.04; H, 3.02; F, 58.7.

The structure of CHF OCH(CH )CF was determined by elemental analysis and by n.m.r. and infrared spectra.

In order to determine the potency of 1,1 .l-trifluoro- Z-difluoromethoxy propane as an inhalation anesthetic in combination with oxygen, a series of tests were carried out on mice. The 1,1 ,l-trifluoro-2- difluoromethoxy propane used was at least 99.8% pure as deterined by vapor phase chromatography.

Groups of five mice were placed into a jar and exposed to a concentration of 2.5% by volume of CHF OCH(CH )CF After an average induction time of 0.70 minutes, which was free of excitation, the mice were anesthetized. During the period of anesthesia the mice showed no change in respiration and no visible change in color. A good anesthetic syndrome was produced and the mice were maintained in a light plane of anesthesia. The mice recovered in about 0.25 minutes following removal from the jar and showed no after effects.

Groups of five more mice were then given a similar test with 7.5% by volume of the compound. After an average induction time of 0.25 minutes an excellent anesthetic syndrome was produced. Anesthesia was deep and relaxation excellent. The respiration remained normal throughout the period of anesthesia. The induction period was very smooth with no apparent excitation. On removal from the jar the mice fully recovered in about 0.75 minutes.

The compound l,l,1-trifluoro-2-difluoromethoxy propane exhibits excellent anesthetic properties in inhalation anesthetic susceptible mammals. The compound lends itself to effective use as an inhalant anesthetic in respirable mixtures containing life-supporting concentrations of oxygen. In addition, studies with the agent have shown that it is highly potent, affords good muscular relaxation. is nontoxic, has a high margin of safety, affords rapid induction free of excitation and rapid recovery, and affords ease of control of the level of anesthesia.

The effective amount of CHF OCH(CH )CF to be employed depends on the level of anesthesia to which the mammal is to be brought, the rate at which anesthesia is to be induced. and the length of time over which anesthesia is to be maintained. Volume percentages of CHF OCH(CH )CF in oxygen from a few percent up to several percent. can be employed. The person controlling the anesthesia can easily regulate the amount of CHF OCH(CH )CF to be used starting with a small amount of the ether and gradually increasing the amount until the desired plane of anesthesia is reached. By then monitoring the physical properties of the mammal, as is the usual procedure, the duration and plane of anesthesia can be readily controlled.

It should be understood that the foregoing disclosure relates only to a preferred embodiment of the invention and that it is intended to cover all changes and modifications of the example of the invention herein chosen for the purpose of the disclosure which does not constitute departure from the spirit and scope of the invention.

What is claimed is:

l. The compound 1,l,1-trifluoro-2-difluoromethoxy propane of the formula CHF OCH(CH )CF 

1. THE COMPOUND 1,1,1-TRIFLUORO-2-DIFLUOROMETHOXY PROPANE OF THE FORMULA CHF2OCH(CH3)CF3. 